Philae's Lost Seven Months Were Completely Unnecessary 419
StartsWithABang writes: This past weekend, the Philae lander reawakened after seven dormant months, the best outcome that mission scientists could've hoped for with the way the mission unfolded. But the first probe to softly land on a comet ever would never have needed to hibernate at all if we had simply built it with the nuclear power capabilities it should've had. The seven months of lost data were completely unnecessary, and resulted solely from the world's nuclear fears.
But how would it hug the comet... (Score:5, Funny)
With nuclear arms?
Re:But how would it hug the comet... (Score:5, Funny)
With nuclear arms?
That warm soft glow isn't radiation, it's love!
Re:But how would it hug the comet... (Score:5, Funny)
With nuclear arms?
That warm soft glow isn't radiation, it's love!
If it was an ice comet it wouldn't glow, it would melt. Defeating the purpose of sending a probe there.
How many probes does it take to get to the center of a 67P/Churyumov-Gerasimenko?
Re:But how would it hug the comet... (Score:5, Funny)
How many probes does it take to get to the center of a 67P/Churyumov-Gerasimenko?
The world will never know.
Re:Not fear but precaution (Score:5, Interesting)
Re:Not fear but precaution (Score:5, Interesting)
The article's understanding of things is no better.
The reason we don't use Pu238 more as a primary power source isn't NIMBYs - it's because we're almost out of it and it's absurdly expensive. Pu-238 isn't a "waste product" (except as mixed in with other isotopes and costing a fortune to isolate), it's a manufactured product - and with all transmutation, that means "slow" and "taking up neutronicity that could otherwise be going towards generating power". The plutonium to fuel Philae would have not only cost us a lot but also robbed us of the potential of an outer planets mission until our work to increase plutonium production catch up to our consumption.. It's just not worth it.
I agree with the author about heaters - sort of - but that's really a rather minor point compared to the bigger picture. As it stands, no, they should not have powered Philae with an RTG. And be freaking patient, Philae got to observe the surface when it was cold and is now getting to observe it hotter than we ever thought we'd get the chance to observe. And more to the point, you can't shut off an RTG or a radiothermal heater. Meaning if Philae had been nuclear, it'd be overheating today.
Re:Not even that... (Score:5, Informative)
Obligatory reading (Score:5, Interesting)
Re:Obligatory reading (Score:5, Insightful)
To answer this specific engineering problem, plutonium is simply too dangerous and costly to use in space. The reason is that plutonium is actually very safe to humans except when breathed in as small particles, such as what might be generated when a launch vehicles catastrophically explodes on launch. In this case, the small particles will tend to be inhaled by animals, pass through the lungs, and pretty permanently become part of the body. The plutonium will then go though the 24,000 half life, which means over the lifespan of the contaminated human almost no Pu will decay. It will radiate and cause health issue for a lifetime.
Again, this is an engineering problem with very smart people working it. All engineering problem result in an engineering solution, and an engineering solution is always a compromise between competing factors, some technical, some emotional.
In hind sight it is always easy to poo poo an engineering solution. People who do nothing but push paper, like the readers or forbes, are the most likely candidate is simply say 'why did we do this'. They can ask that question because they have never created a practical device in their lives, therefore never have been part of the engineering process and therefore have never understood that the result is always a less than perfect but usually quite acceptable solution.
While the nuclear power proponents want us to believe that nuclear power is the solution to everything, history tells us otherwise. Even though nuclear power is very mature technology, there is little private funding for it. In the US Nuclear power plants are not being build because bankers know there is no profit in it, and government should no more subsidize a nuclear power plant than a coal fired plant. Both are mature enough to stand on their own.
Nuclear power cannot stand on it's own because it cannot generate enough profit. For instance, BP generates enough profits so that when the Deep Horizon rig failed it could cover the 13 billion dollar clean up. Fukushima is going to cost 10 times that much to clean up. Who is going to pay for that. They taxpayer. The US taxpayer for contamination that reaches US land and water. It is true that the readers of Forbes loves to make profits at taxpayer expense, but I don't think that it is a good idea. It is only free if you are not the one impacted.
Re:Obligatory reading (Score:5, Informative)
the 24,000 [year] half life
TFA refers to Pu238, which is quite active. It has a half life of about 88 years. It is an energetic alpha emitter, which is not dangerous outside the body because the skin absorbs the emission and you can wash Pu238 off pretty easily. However, once it's inside you, virtually all of the alpha emissions will be absorbed by your body unless/until you can excrete it. A good fraction of any amount ingested will eventually emit energetic radiation that you will absorb. A disaster could be bad.
Having said all that, including Pu238 in a spacecraft is a problem we [wikipedia.org] have [wikipedia.org] solved [wikipedia.org] before [wikipedia.org], so it's not all that crazy.
Re:Obligatory reading (Score:4, Insightful)
Love your explanation of why engineering problems are hard (everything is a compromise of something else, nothing is as simple as it first seems), although I disagree with you about nuclear power. Why should "how much money it makes" be the ruling metric? That's extremely foolish. Despite the high-profile cases, nuclear power is actually one of (if not the) safest forms of power generation. We are ruining people's health and the environment by using things like coal, so we need an alternative. So, nuclear power doesn't make lots of money - so what? If that's all we are measuring things by, then it explains why so many things are screwed up. Apply the same engineering thinking you explained to the performance metrics question: any single-metric performance measurement will be wrong ("good" overall is measured by a number of competing and sometimes conflicting factors; so, in your case "profitability" is a poor reason to say "nuclear isn't a solution").
The prevention and clean-up do need to be factored into the use of nuclear power, but we also need to drag the technology forward to safer designs, not keep limiting it to unsafe, inefficient forms that haven't changed in half a century.
Re: (Score:3)
incompetent people should have nothing to say about it
Dude, wake up and smell the democracide. A nuclear engineer has just as much vote on this matter as a guy who can't figure out the coffee maker at 7-11.
Re:Obligatory reading (Score:4, Insightful)
Have there been? 10,000 people die in Japan from a tsunami and everyone is still shitting their pants over a nuclear reactor that didn't kill anyone. People fear what they don't understand, and most of us aren't physicists.
Re:Obligatory reading (Score:5, Informative)
And people go "oh no they can detect the radiation IN CALIFORNIA ITS LIKE THE TITANIC BUT WITH BEARS EVERYBODY PANIC!!11111ONE!11ONEoneleven1!11"
Which is actually a testament to the astonishing sensitivity of modern equipment. The level of radation in california is 8 disintegrations per cubic meter per second. That's 8 whole atoms per second in a tonne of water. That's 8 out of 100000000000000000000000000 atoms (that's actually the right number of zeros give or take).
It's also about an order of magnitude below the background radiation from naturally occuring stuff in the water, never mind the incoming cosmic rays and stuff from the ground and food.
Another fun fact: the Super-K detector can pick up the signature from relatively nearby nuclear submarines that aren't leaking any ionising radiation at all.
Instruments are sensitive.
Re: (Score:3)
I've read somewhere that radiation detectors often alarm in ports because of bananas. Bananas are rich in potassium, which is slightly more radioactive than average matter. Which is quite impressive - we have developed really precise sensors. But most of the people would understood this as a proof that we have developed really radioactive bananas.
Actually, eating one banana per day increases your risk of getting a cancer as much as smoking half of a cigarette per year. Of course, getting potassium is good t
Re: (Score:3)
WTF does all this shit come from? How does such a misunderstanding of background radiation balloon into something so beyond the far side of crazy as claiming eating bananas are more of a health risk than Big Macs? I can only assume that somebody has assumed that all of the potassium in a banana is the very rare radioactive isotope and run from there. Also the detector shit is a fair
Radioactive Californians (Score:3)
The level of radation in california is 8 disintegrations per cubic meter per second.
If correct then that rate is far, far lower than the level of radiation in Californians. The tiny amount of potassium-40 in the human body produces 4,400 disintegrations per second [wikipedia.org]. Then there are other isotopes such as carbon-14 to consider so the actual rate of decays will be even higher. In fact if we assume the average Californian has a mass of 80 kg and a density roughly equal to that of water then the decay rate per cubic metre of Californians is just under 55,000 decays/second or 6,875 times your ba
Re:Obligatory reading (Score:5, Informative)
While it is true that people are not dropping dead in the thousands due to Fukushima, I'll leave this to consider:
Whether the estimate is correct or not, it will take decades before it's safe to say "a nuclear reactor that didn't kill anyone". The actual outcome will also largely depend on how well the Japanese authorities will handle the cleanup. Judge for yourself whether they've done a good job so far.
Re:Obligatory reading (Score:4, Insightful)
After Chernobyl we heard the same predictions, initially of "millions of excess deaths." Exactly the sort of handwavy pseudo-statistics the flat-earth lobby outgasses when it doesn't have any real science. But after all those yaers, the Chernobyl death toll remains stubbornly at 51.
But to stay on topic: supposedly the reason Philae did not have a radioisotope generator is that these are rather large, roughly the size and mass of a person. This would have been more useful for a long-endurance version of the Rosetta itself than a small lander probe.
Re:Obligatory reading (Score:5, Insightful)
But after all those yaers, the Chernobyl death toll remains stubbornly at 51.
Right, there's no way to accurately count the people who succumbed to various illnesses which wouldn't have killed them if not for its influence, so it's never going to be incremented substantially, but it will also never accurately reflect the impact of the Cherbobyl disaster.
Re:Obligatory reading (Score:4, Insightful)
I chalk up the deaths of Chernobyl less to nuclear power, and more to being the risks of living in a place like the Soviet Union. Yes, you can set off nuclear plants like that, but let's face it, Chernobyl was a triumph of Communist bureaucratic indifference at work.
Re: (Score:3)
Right, there's no way to accurately count the people ...
There is a very powerful tool called epidemiology [wikipedia.org].
In simple terms, you look for an increase in disease rates over time compared to a control population.
In the case of Chernobyl, there is far less effect than was expected. There has been a small increase in childhood thyroid cancer (treatable, BTW), but not much else. No detectable increase in Lukemia or adult cancers. The predictions were overwhelmingly pessimistic.
In Fukushima, the radiation effects can reasonably expected to be much smaller for a number
Re:Obligatory reading (Score:5)
I already said that "whether the estimate is correct or not, it will take decades" because of "the long latency period for some cancers [theecologist.org]. WHO said in 2005 [who.int]: "The total number of deaths already attributable to Chernobyl or expected in the future over the lifetime of emergency workers and local residents in the most contaminated areas is estimated to be about 4000." Again, the numbers do not matter, or that they only look at the "most contaminated areas" in their estimate. All I was saying was that it is too soon to talk about the death toll, because it will take decades of science to say anything meaningful. The OP argument was like "I locked up 10 people in an airtight room and they were all ok when I checked on them a minute later."
Re:Obligatory reading (Score:5, Insightful)
That's a statistic I'd find hard to believe. And besides, immediate death is just a small part of it. There are a few hundred people that were in the Russian army at the time and had to respond to the disaster who have either died of various cancers or are suffering from them now. There are kids in Ukraine that are born with many genetic defects, like holes in their hearts, presumably because their parents were affected.
I wouldn't count this out as a negative effect. And these are obvious effects. How many people there suffer from lesser ilnesses that might or might not be attributed to Chernobyl, like stroke, cancers, etc.
I'm not opposed to nuclear. I think it needs to be a viable option if we are to stop producing CO2, but I won't pretend that it's harmless, either. Even if we get to a 100% safety record, there's still the matter of storage, and transporting that waste to the storage areas. How many TEPCOs do we need to realize many of these companies entrusted with the task can be very incompetent and borderline criminal in ignoring safety lapses pointed out by inspectors.
Re: (Score:3)
I'm not opposed to nuclear. I think it needs to be a viable option if we are to stop producing CO2, but I won't pretend that it's harmless, either. Even if we get to a 100% safety record, there's still the matter of storage, and transporting that waste to the storage areas. How many TEPCOs do we need to realize many of these companies entrusted with the task can be very incompetent and borderline criminal in ignoring safety lapses pointed out by inspectors.
You're not opposed to nuclear, but you still fall prey to the severe lack of knowledge most people have regarding nuclear power generation. It's really simple: if the waste is so dangerous as to need storage that can last centuries, as is currently the case, it's because it's overwhelmingly still fuel. It's been "poisoned" in the reaction process, but can be reprocessed into usable fuel. However, the US has stopped all reprocessing activities, which means that the fuel is immediately disposed as soon as its
Re:Obligatory reading (Score:4, Insightful)
Are you sure its radiation hasn't killed anyone? I've seen several "news" articles that claim a death toll of over 10,000 spread across the pacific, including thousands in California.
Sarcasm aside (and the above is true, in that those "articles" are floating out among fringe "environmentalist" sites), a HUGE part of the problem is in domestic nuclear industry that isn't replacing plants far past their operational lifetime with the newer and MUCH safer designs, since that would cost real money and the stockholders want that to be reexamined next quarter, after they sell. And short. Greed and stupidity on both sides...
Re: (Score:3)
No people aren't replacing plants because every time they do some idiot NIMBY kicks up a stink about building a "new" reactor. Investment money has nothing to do with it. There are plenty of people willing to invest if the artificial hurdles weren't so grand. Case in point look at the story /. ran a few months ago about a "new" reactor built in Indonesia. This site alone had idiots talking about it being risky building a reactor close to a city ignoring that it was a replacement reactor at an existing power
Re:Obligatory reading (Score:5, Funny)
Re: (Score:2)
And what does a few grams of plutonium have to do with nuclear power plants blowing up?
Re: (Score:3)
Re:Obligatory reading (Score:5, Interesting)
Obligatory raidiating (Score:3)
Re:Obligatory raidiating (Score:4, Informative)
Re:Obligatory reading (Score:4, Insightful)
Not necessarily. Time won't solve basic physical limits. Chemical batteries, as most will know, have very limited lifetimes. The RTG on Voyager 1 has been going for more than 37 years. If you rule out radioactivity or nuclear power, then your only options in space are chemical or something like solar. Solar has problems, as Philae has demonstrated. The issue with chemical is that there are hard limits on how much energy you can store in the bonds between atoms - even if we invent a wonderful new rocket fuel or battery type, the maximum limits can still be worked out and they will never exceed that (there's a reason why we use ion engines for space probes, and it has to do with "mass you have to carry" and "how much it can change your speed"). "More technology" will never overcome these problems, unless you come up with something really exotic (like zero-point energy). One that is easy to understand is solar on Earth: we can make it more and more efficient, but we can never exceed 1kW/m^2, as this is the total amount of solar radiation reaching the surface (and, I don't think we've got better than about 30% efficiency). It doesn't matter how wonderful your technology gets, it can never beat basic physics.
The only "high-yield, low launch risk" technology I could think of would be fusion (as deuterium isn't radioactive), but we are yet to get that viable. Apart from that, you're dreaming of magic, no matter how much time you wait.
Nuclear Power Fears (Score:5, Insightful)
Re: (Score:3)
Really?
New Horizons?
It is not taboo at all except for a few loud nut cases.
Re:Nuclear Power Fears (Score:5, Insightful)
Well, yeah, if you pick a synthetic radioactive source with a half-life longer than humanity's been in existence.
Strangely enough, nobody's fucking idiot enough to do that.
Re: (Score:2)
If it has a half life longer than humanity's been in existence, it can't be very radioactive.
Re: (Score:3)
Re:Nuclear Power Fears (Score:5, Informative)
Radioisotopes that last "longer than humankind has been in existence" are so weakly radioactive, and so small a part of a nuclear event, that we can ignore them. The most dangerous isotope in an accident is I-131, which has a half-life of eight days. That's a lot of energy it has to release in a short time.
Re: (Score:3)
It's the first couple minutes of the flight that people are worried about.
Re:Nuclear Power Fears (Score:4, Insightful)
RTGs are deigned that even in the event of a rocket breakup (the rocket makes a big boom), or reentry (blast furnace for 30 or so seconds), that the RTG will not breach, and will frankly land (hit the ground pretty damn hard) without any possibility of damage. You are more likely to die from getting hit by the thing than any possibility of radiation from the thing, unless you disassemble it.
Nuclear Power? (Score:2)
I thought one of the projects goals was to do things within a budget especially considering how many nations in the EU were involved in building it. [www.dlr.de] You'd probably only see a single nation sourced spacecraft with this kind of capability.
HÃ? (Score:5, Interesting)
and resulted solely from the world's nuclear fears.
What bollocks is that? What has an RTG in space to do with a nuclear (fission) reactor on earth?
No one cares how you power your satellites, space probes.
I for my part have no back yard on a comet light minutes away.
Re:HÃ? (Score:5, Informative)
What bollocks is that? What has an RTG in space to do with a nuclear (fission) reactor on earth?
Nevertheless, a bunch of fearful and uninformed people vigorously protested Cassini and it's RTG. Sky is falling, something something we're all going to die!
Re: (Score:3)
Re: (Score:2)
Learn to read. Burn your keyboard.
Re: (Score:2, Informative)
Has all to do. Fear of RTGs caused a lot of noise surrounding Cassini [nytimes.com], which went on and echoed. By the time Rosetta/Philae were designed, as stated in TFA:
All previous deep space probes have used RTGs [Radio-isotope Thermoelectric Generator], but the ESA has not developed RTG technology. They couldn’t get it from NASA (who wouldn’t provide it) or Roscosmos (which would violate the ITAR treaty).
Re:HÃ? (Score:4, Interesting)
Actually, the RTG would have survived had the launch vehicle exploded. It also wouldn't be the first RTG to re-enter the atmosphere.
meanwhile, they missed the boat on the launch, so they protested the Earth slingshot maneuver instead.
Aborted launch (Score:3)
What bollocks is that? What has an RTG in space to do with a nuclear (fission) reactor on earth?
No one cares how you power your satellites, space probes.
I think the fear was that if the system broke up on launch (exploded, perhaps) that it would strew radioactive materials over a wide swath of landscape.
(To be fair, we've had a couple of satellite launches screw up in the last decade, so the probability of failure isn't zero.)
Re:HÃ? (Score:4, Informative)
Space probes do get started on earth, and have to go through a somewhat unreliable launch process to get to space. There is a fear that if the rocket were to blow up, radioactive material released into the atmosphere would be dangerous.
It almost certainly wouldn't be. Even in the worst-case scenario, that the RTG vaporized on reentry, it would be heavily dispersed. Still, NASA calculated for a similar case, there could be several thousand deaths [nasa.gov] (page 66). (Not that you could peg any one death to it, but rather thousands of additional cancers compared to not having an accident with an RTG launch failure.) Plus some land contamination with radioactive dust.
So it's not completely insane to be concerned. They figure your personal odds of dying because of it to be one in a trillion, which most of us would say is too low to think about. But I can understand why a few people might say that even one-in-a-trillion (especially since it's repeated for everybody on the planet) is worth considering. It's not as simple as having it millions of miles away in space.
Re:HÃ? (Score:5, Informative)
Yeah, that table is based on LNT, a "theory" with less supporting evidence than Santa Claus. Actually, that's not fair to Santa, since the evidence directly contradicts LNT. But LNT is mandated by law in many cases, which you should keep in mind the next time someone tells you that the left is pro-science.
LNT is "Linear, no threshold". According to that nonsense, a radiation dose expected to cause cancer in a person, but distributed over 7 billion people still causes 1 "extra" cancer in the world. This dose may not even be detectable, by the way, and would be far smaller than the ordinary background radiation levels.
In reality, people with occupational radiation doses have lower cancer rates than the general population.
Re:HÃ? (Score:5, Informative)
In fact, there is NO valid example of a LNT toxin in nature. If you reduce the concentration of any toxin in, say, water, there is always a point at which its medical impact drops to zero while there is still some toxin present. This is because natural selection ensures that we can survive the amount of that toxin that we normally find in the environment. This includes the constant drizzle of background radiation that we live in.
In fact, the scientific term for belief in LNT in chemistry is "homeopathy."
Re:HÃ? (Score:5, Interesting)
What bollocks is that? What has an RTG in space to do with a nuclear (fission) reactor on earth?
Pu238 is produced in reactors here on Earth. Due to all the restrictions and red-tape put up by (supposedly) anti-nuclear activists, it's difficult and very costly to keep producing it, so everybody who had been producing it, simply shut down.
Now to be honest though, this is a poorly constructed argument. Strict regulation of nuclear materials isn't in itself a bad thing and besides, the lack of Pu238 is mainly due to the shutdown of the nuclear weapons industry, not the power industry (which never produced it anyway). Moreover, Philae was a low-value part of the mission to begin with and an RTG wasn't really necessary (needless to say that it can weigh quite a bit, potentially sacrificing other experiments that could be carried in its stead). Regardless, the comet was scheduled to make a close pass by the Sun regardless, so there was always the possibility of getting more power later on in the mission. Where the RTG argument *can* make sense is in missions like Juno [wikipedia.org]. Juno had to go to some pretty serious compromises to be able to explore Jupiter without an RTG, such as having oversized solar panels for its relatively meager scientific payload. Had Juno had an RTG, it would likely have been able to pack a lot more equipment that is also more power-hungry, allowing us to get more out of the mission. Anything beyond the orbit of Jupiter without an RTG is an outright non-starter using solar power, as the scientific return quickly diminishes to zero simply due to the lack of power. Even Mars missions without RTGs were compromised (one of the principal reasons Curiosity got an RTG was so that we could get more power-hungry experiments on it, cause being able to snap pretty pictures only gets you so far).
Overall, it's a soapbox article and sadly, it starts out with the wrong premise.
Not nuclear fear (Score:5, Informative)
Firstly, what caused the problem was not "Nuclear fear", but failure of the harpoon to hold Philea down. The solar panels would have worked fine otherwise.
Secoundly, Plutonium-238 is simply no longer available - nobody makes it anymore. The reason why is because it is created using a dangerous and expensive process by irradiation of neptunium-237.
Re: (Score:3, Informative)
Thirdly, the lander was "bonus", an "extra" and had to meet very tough weight limits. There was simply not enough mass available on the rocket to put anything but light weight solar.
Why is this even being brought up anyway? They couldn't launch with an RTG because rocket didn't have enough capacity.
Re: (Score:3, Informative)
RTFA.
The probe as built contained solar panels massing a little over 12 kg, and the plan depended on a perfect landing to get maximum solar exposure. Imperfect landing -> bad solar angle -> not enough power -> probe dead for seven months.
The RTG and support stuff would have massed about 12 kg and would not have required the perfect landing.
TL;DR - The RTG would have weighed the same as the solar panels, in a considerably smaller physical envelope, meaning it would have been EASIER AND CHEAPER to i
Re:Not nuclear fear (Score:5, Interesting)
Still doesn't mean the solar panels aren't cheaper and more effective for the mission, at the cost of some additional risk. That's how engineering works: you don't get unlimited budget to drive risk to zero.
The important thing to realize here is that events have actually validated the engineers' choice to use solar. Had the interesting stuff been happening out at 5+ AU where you'd only be getting only 5% as much solar radiation as Philae is getting now, then failure to orient the lander ideally would have meant mission failure. But that's not the case. The interesting stuff is happening *now* around perihelion, where there's boatloads of solar radiation available even if the solar panels aren't pointed just so. There is not very much if anything substantive lost by the interim inactivity of the lander, other than a few years life expectancy for the program managers.
Given that we now know that the nitrocellulose powering the harpoon system is unreliable after ten years in a vacuum, you wouldn't design the lander the same way today. You might even choose to use an RTG; I don't know. But this result certain bears out the engineers' assessments of the net prior probabilities; in fact the current outcome was no doubt one of the possible scenarios the engineers considered and put in the success column.
Re:Not nuclear fear (Score:4)
RTFA.
I did. I was not impressed.
We have NO idea whether anything "interesting" was happening during that time.
Well, like what, for example? What were you expecting to happen?
Your definition of "success" is "Well, it works now, because we got half-lucky on the landing."
My definition of success in this case is collecting the data which were used to cost-justify the mission. Do you have a better definition of "success"?
For whatever reason, you choose to disregard the fact that using an RTG would have eliminated that risk altogether, *and* it would have eliminated that seven month blackout period.
Because the mission will be successful according to my definition of "success" (see above). You seem to have a "cost is no object" mindset. Since the ESA does not have any of its own RTG technology it would have to buy it from the Russians or Americans, and then build in the necessary safeguards required by the mission profile's three near-Earth fly-bys. Since solar panels are cheap, simplify the mission, and the ESA has access to high-efficiency solar technology that can do the job, it makes sense to use them.
Your definition considers total mission failure, from a less lucky missed landing, an acceptable risk.
Of course it's an acceptable risk. If total mission failure were not an acceptable risk, then the mission would be too expensive to conduct.
Re:Not nuclear fear (Score:5, Interesting)
For a space launch, the RTG needs to be protected in case of launch failure and will weigh more then 12 kg. The ones currently used weigh 57 kg compared to Philae's 21 kg.
I also question whether putting a heat source (300+ watts of heat to equal the required 32 watts) on an ice ball would be smart
Pu-238 was available when it launced (Score:3)
Philae was launched in 2004. NASA launched a Pu-238 radioisotope thermoelectric generator (RTG) as part of the Mars Science Laboratory in 2011 [wikipedia.org], and a Pu-238 RTG was being designed by NASA as late as 2013 [wikipedia.org]. Even if your claim is true, and Pu-238 became unavailable in the last two years (I doubt it), Pu-238 must have been available in 2004 since it was available as late as 2013.
Moreover, while Pu-238 has been used for the majority of space RTGs. It's not the only element that can be used. U-235 was used in spa
Re: (Score:2)
Here's what Wikipedia says about it:
"The United States stopped producing bulk plutonium-238 in 1988;[5] since 1993, all of the plutonium-238 used in American spacecraft has been purchased from Russia. In total, 16.5 kilograms have been purchased but Russia is no longer producing plutonium-238 and their own supply is reportedly running low"
In fact, the Horizons project only got their supply by salvaging a spare from the Cassini mission.
Re:Pu-238 was available when it launced (Score:5, Informative)
I think you are nitpicking the definition of "available". Yes, the fuel existed at the time, that doesn't mean the fuel was available for this mission. A high risk, relatively low reward, limited life lander almost certainly doesn't merit using 1/10th of the available reserves.
Don't think it was high risk? The lander failed in multiple different ways on deployment and was able to do science by little more than dumb luck (not discounting their success, dumb luck plays in important part in everything and it was their engineering and planning that allowed the landing to succeed despite those issues). Don't think it was low reward? Most of the science the lander was designed for was completed on batteries during the 60 hour window after landing. Don't think it's limited life? In a few months, the comet is going to start out gassing and the lander will almost certainly be disabled.
If Pu-238 were still in production the math works out differently. If the lander had been a more central part of the mission it might be different. If the comet were on it's way out of the system instead of in that could change things too (though then Rosetta would also need an RTG). The point is: it's not binary. It's not "the fuel is right there lets use it". There's a cost, and a benefit to using it in this probe rather than the next one.
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The plan did go through. US production restarted in 2013 [popsci.com].
Re:Not nuclear fear (Score:5, Informative)
Plutonium-238 is simply no longer available - nobody makes it anymore.
That's pretty much what's in the article. The summary is inflammatory (on Slashdot ? Who would have guessed ?). :
The meat of the argument is this
So : side effects of nuclear regulations, and lack of material.
By the way, weight was not a reason, RTG weighting about the same as solar panels (12kg).
Why oppose nuclear powered satelittes? (Score:4, Insightful)
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If it was political, that is sad (Score:3, Insightful)
(The following assumes that politics was the cause of not using Pu-238...) The toxic stuff had a half-life of only 88 years, and was encased in another element? AND only a few grams were necessary to power it for the entire mission? I'd expect that kind of fear and ignorance from politicians, but project managers overseeing projects like this need to cut through that FUD with facts gleaned from their knowledgeable subordinates.
I guess that going green doesn't always lead to a green light of success at the end of the mission.
Re:If it was political, that is sad (Score:5, Insightful)
Re: (Score:3)
I already posted, but I would bet that they just couldn't get any Pu-238 if they had wanted it. The stuff is in really short supply now. The New Horizons mission to Pluto launched with a less than the desired amount because it wasn't available. The Juno spacecraft enroute to Jupiter doesn't have any and was designed for solar power.
http://www.universetoday.com/1... [universetoday.com]
Stealing our fun? (Score:2)
/. has commenters to provide a daily (ok, hourly) dose of whining over why some huge and largely successful research project or whatever got it all wrong because they didn't use some pet technology, where said technology would only have worked under ideal circumstances (i.e. a world in which everyone is totally cool with nuclear power) and in reality would have been completely impractical* due to, well, reality. If the article itself is a poorly designed rebuttal requiring billions of people to fundamentall
European spacecrafts don't have muclear power! (Score:3)
After gulping the ad, you see a bunch of fossil photos from Philae, then a very basic pledge for embarking a small radioisotopic thermal generator (i. e. nuclear power).
This is silly twice.
First, because Philae is an entierely European craft, and there are just no space nuclear generators in Europe. You can call it wrong, but even on the European Huygens probe the much simpler nuclear *heaters* were US-provided.
Second, because the only available US RTGs are very big and heavy, and mass on this very light craft would totally have prevented to reuse an existing design. You can advocate one could have developed a miniature thing outputting just some watts. You would have been *wildly* out of budget.
So, well. A basic pledge for nuclear power in space, yes, be it good or bad.
But taking Philae as an example is a very wrong way to do get it. Self-deserving even, maybe.
If they'd only played Kerbal (Score:2)
Everyone knows you need to tack on a PB-NUK to every probe if you'll be out of sunlight for longer than the batteries hold a charge.
Complete Hogwash (Score:3, Insightful)
It would have been totally ludicrous to equip Philae with a RTG. This would have meant a dramatically increased cost for probably little gain. The main mission is the orbiter - it works fine with solar panels. The lander had an estimated failure probability of 50%, and that was an optimistic estimation. In the case it lands, the lander was equipped with a battery for the prime scientific objective. For the icing on the cake cheap solar panels were added.
So this guy suggests to spend hundreds(?) of thousand Euros just for the totally unlikely event that a) the lander lands correctly and b) the lander bounces and c) the lander lands again in a shadow for d) the icing on the cake? He does not seem to understand how budgeting works.
Use RTGs for deep space missions, where they are needed.
How can this ignorant (or simly troll?) be a "NASA columnist"?
severe plutonium shortage (Score:3)
http://www.wired.com/2013/09/p... [wired.com]
The US doesnt manufacture the kind they need. They got some from dismantling Russian warheads, but no longer. The upcompiong Juno-Jupiter mission was converted to solar power, about the distance limit they can do with solar cells.
The Americans pulled out (Score:4, Insightful)
First of all, the Rosetta mission was a joint NASA-ESA mission, where NASA was in charge of providing the power supply. However, the US Congress pulled the funding on the mission and ESA had to do it alone. This was after most of the spacecraft was already designed.
Second, ESA never developed nuclear-powered spacecraft. Even though it is a policy choice due to the fears of blowing up nuclear material in the atmosphere, it is also reflection of a space agency created specifically for non-military purposes. While NASA is also a civilian agency, it has a strong connection with the US military and access to materials such as plutonium.
Third, different Nuclear Power sources in Space (NPS) have to be developed in order to guarantee the availability of the raw material. There is no point in developing a long-term programme based on rare or very hard to obtain nuclear materials.
Quite simply... (Score:3)
People who are the most concerned about nuclear energy understand these facts:
1) High-level radioactive waste is deadly to touch, hold, carry, etc., for hundreds of thousands of years. You can pick up a piece of this waste, hold on to it for a while, and be dead in a few days. Perhaps you picked it up, studied it for a while, and dropped it in the space of 15 minutes because it was sitting a pile of rocks.
2) Homo sapiens, our species, is believed to be between 100,000 and 200,000 years old.
3) We've only had writing for about 5,000 years, and in certain countries in sub-Saharan Africa only about half the population is literate in ANY language. Before the modern era, it's thought that no more than 40% of the world population was literate.
4) As we all know, the most advanced civilizations decline and are sometimes replaced by primitive civilizations. Among many other causes, formerly fertile land can become arid. Formerly great civilizations in Central America are now jungle with isolated tribes. Formerly fertile Northern Africa is a now great desert habited by nomadic people and not much else.
5) The world is ignorant about geology. We have no idea how to do fracking safely, even though it could probably done safely. The reason is we don't have enough understanding about how the ground beneath our feet works.
Nuclear energy, in its present form, produces a waste product that will outlive our species. We all hope that Homo sapiens will evolve into a better species, but there is no guarantee of that. Perhaps there will be a Homo successor that is more primitive. We can guess what that species will be like, but we're just guessing. It is of paramount importance that we are able to communicate with that successor species. Then we need to find a place to put the waste on Earth that is geologically sound, yet we can't even drill for oil safely without causing earthquakes. Good luck with that.
The inevitable will happen and the waste will somehow surface. Let's say that there is ample signage. How good are you at Sumerian cuneiform? I'm not so good at it, either. In fact, I don't even know a single symbol. At one time cuneiform was the premier go-to language, the English of its day, and it is only about 5,000 years old, give or take a few thousand years. If radioactive waste was labelled in cuneiform, I'd have to retain a scholar to understand the risk of the material. Can you even imagine how dissimilar a language 500,000 years from now will be from English? That's 100 times as long as the whole history of writing.
We're kidding ourselves by thinking this energy is clean. What we are doing, actually, is poisoning the land for hundreds of thousands of years. The built-in assumption exists that we'll be so advanced techologically speaking by then that future residents of Earth will have no problem dealing with any of it. In fact, I believe that the oppposite is true. We can't depend upon steady progress. Progress has always been in fits and starts, with intense periods of decline, and at times entire civilizations have dropped off the face of the Earth.
Re: (Score:3)
No, it's not. The stuff that kills you if you stand next to it has half-lives below 50 years, which means that after one or two thousand years, there's hardly anything left of the original amount.
The isotopes with half-lives in the thousands of years don't emit enough radiation to give someone deadly radiation poisoning in a few minutes, but they will raise cancer rates if released into the environ
Reasons we didn't use RTGs (Score:3)
1) The previous Slashdot discussions on Philae [slashdot.org] include some insightful comments on RTGs.
2) The Forbes article says that the project manager, Stephan Ulamec, cited political reasons for not using plutonium. There is no quote attributed to that, but another forum claims that it is in the youtube interviews of him. If he truly said this, shame on Forbes for not quoting him directly and leaving it uncited.
At ESO with the leading scientist behing Roseta (Score:3)
Funny enough, just today I was watching a presentation in ESO with one of the leading scientists in this project. And it's a bit more complicated than I thought.
Unlike NASA, ESA never applied this technology, so they can't just use it in space probes. They would have to get in a partnership with NASA or to allow some years for the engineering teams working with them to find out how to use the technology correctly (we are talking about systems with very limiting energy and weight requirements here).
Then, even if they know how to apply it correctly, the probe would be launched using an Ariane taking off from French Guiana and, by French law, any nuclear device transiting in French territory would need to have an express signed order by the French president, allowing it.
I totally agree this is a baseless fear, but now, we are so deep into it that even if we wanted to use a nuclear power source, we would need to do it with great effort.
Best piece of the article is (Score:3)
First, is correctly states that ESA does not have an RTG and cannot acquire one, due to the lack of a seller. And then secondly, he claims (without proper reference, and I could not find any)) that this is due to political reasons. However, what you need to develop an RTG is (a) money and (b) Plutonium-238. This requires reactors capable to develop nuclear weapons material. While the US has only a few bits left from their program, certainly France and the UK do not have that much around. And other states, like Germany, do not have nuclear weapons and the means to create enough Plutonium without violating treaties. Therefore, an RTG is not an option.
Unnecessary (Score:4)
The seven months of lost data were completely unnecessary,
A dangerous proposition. Some might counter it by questioning just how much the Philae's mission was really "necessary", and not just huge waste of funds and resources.
and resulted solely from the world's nuclear fears.
Or probably because world wants to push scientists to find alternatives?
Anyway. Nuclear power is one of those "not in my backyard" things. It's good - as long you live far enough from it. You do not "fear" it, unless it actually hits you. (And I am saying this as a person who as a child actually lived in the ex-USSR's area mildly affected by disaster of Chernobyl.)
Re:Wind is the answer! (Score:5, Funny)
SOLAR Wind turbines!
Re: (Score:2)
SOLAR Wind turbines!
Even if it look like a dumb post with an humoristic purpose, I seriously love this idea and I really wonder, light electron's mass problem aside, if it could ever be realizable.
Re: (Score:3)
SOLAR Wind turbines!
You could build a Crookes radiometer [wikipedia.org], and I assume space is sufficient enough of a vacuum that you wouldn't need the glass bulb.
Re: (Score:3)
Radiometers don't work in a vacuum - the glass bulb is only moderately evacuated. The effect is caused by the expansion and contraction of the air inside.
Re: (Score:2, Informative)
Yes it will, you just have to manually click the "Continue to site" link in the top right corner.
Re: (Score:2, Insightful)
You still browse the web without javascript? What is this, 2005?
Re: (Score:3)
NoScript, because some of us aren't stupid enough to let anyone run anything without our permission. Until you have tried browsing with NoScript, you won't realise actually how much utter rubbish is being hoisted on your browser. I've seen sites with 30+ scripts requesting to run, and really none of those are needed - well, none of those should be needed, but for some incomprehensible reason, a lot of sites won't display basic content without you having JavaScript enabled, which is idiocy on so many level
Re: (Score:2, Informative)
Right-click on offending part of page -> Inspect Element with Firebug -> Right-click on element markup -> Delete Element
4 clicks to un-fuck those pages. Also works against annoying pop-over "modal" div boxes. And just about anything else in the DOM.
It's your computer and your user agent. Make the DOM your bitch.
Re: (Score:2)
As it currently stands, neither solar or other renewables can come close to providing the energy needs of a 1st world country, and as more of the world develops, this need will only increase. That leaves fossil and some form of nuclear. Or, reducing energy usage. Get rid of everyones appliances, vehicles, heat pumps, exotic out of season foods trucked from halfway a
Re:This is an Opinion/Editorial piece (Score:5, Insightful)
Worse, it's not even informed opinion. You can't just "slap an RTG" on a probe and hope for the best. There are engineering, cost, and benefits considerations to make.
I really feel like people forget that the lander was an afterthought. The primary science of the mission was and is being performed by the Rosetta spacecraft. It was a "nice to have" that everyone was thrilled to see work as well as it did but wasn't critical for the success of the mission. Furthermore, it performed the vast majority if it's planned science activities during the 60 hour battery period after initial landing.
Yes, obviously, probes and landers can and do outperform their initial program goals. But treating the lander like a failure when it was anything but is dishonest. Using it as a soapbox to push your agenda (whether it's one I agree with or not) is insulting to the 2000+ people who worked to make the mission the fabulous success that it is and was.
Re:This is an Opinion/Editorial piece (Score:5, Funny)
You can't just "slap an RTG" on a probe and hope for the best. There are engineering, cost, and benefits considerations to make.
I've tested this extensively in KSP - you can, in fact, just "slap an RTG" on probes quite trivially!
Re: (Score:3)
Apollo 13's radioisotope thermoelectric generator (RTG) with a load of Plutonium 238 entered the atmosphere at earth escape speed (greater than orbital speeds) and didn't cause any atmospheric problems. These things are designed to survive launch vehicle explosions. I suspect the main reason that Philae didn't have nuclear power is that the preferred fuel, Pu 238, is in very short supply. No one who has any is willing to share. Spacecraft designers are doing all they can to avoid it just because it is too
Re: (Score:2)
Exactly, the issue is with scarcity of Pu-238 not safety. They are all encased in enclosures that can survive both explosions and reentry.
https://en.wikipedia.org/wiki/... [wikipedia.org]
Re: (Score:2)
If the rocket blew up in atmosphere you would have had to recover the still solid, single piece RTG core. Not only is the total amount of nuclear fuel relatively small, the cores are also designed to survive catastrophic rocket failure intact. RTGs flew on Apollo 12 through 17, the Curiosity rover, nearly a dozen Earth orbiting satellites, the Viking landers, Cassini, New Horizons, both Voyagers, and more. At least one failed to reach orbit, another burned up when it's satellite reentered, another survived
Re: (Score:3)
How about you refute anything he said, as at the time I saw the same comments about RTGs from many on the Philae stories on Slashdot.
The size/weight of the batteries+solar would have been better put into RTG, as it would produce the same power without worrying about the sun being visible. It is a learning experience for ESA, hopefully they take the lessons learned into account on the next probe.
Re: (Score:3)
My understanding is that the typical RTG is well over a hundred pounds (57 kg according to wiki) and this lander only weighed 21 kg. The typical RTG also produces an order of magnitude more power then this lander used and having 4,400 watts of thermal power on an iceball is not the smartest move.
RTG's have their uses, but not on little landers or micro-sats.
https://en.wikipedia.org/wiki/... [wikipedia.org]
https://en.wikipedia.org/wiki/... [wikipedia.org]
Re: (Score:3)
The lander's payload was only 21kg, the all-up mass was just under 100kg.
Re:Whose nuclear fears? (Score:4, Informative)
The claim of the political reason is without reference. However, the article correctly states that ESA does not have RTG technology and no one was selling RTGs at that time.